Dynamic system modeling for control and diagnosis
Dynamic system modeling for control and diagnosis

... Temperature ◦ Measurement units: °C (Celsius), K (Kelvin) ◦ Absolute zero (0 K = -273,15°C) ◦ Measurement is complicated:  Needs a zero point and a linear scale  The thermometer has heat capacity ...
Intro and Basic Concepts
Intro and Basic Concepts

... Fig. 6: To specify a process, initial and final states and path must be specified.  Quasi‐equilibrium  process:  can  be  viewed  as  a  sufficiently  slow  process  that  allows  the  system to adjust itself internally and remains infinitesimally close to an equilibrium state  at  all  times.  Quas ...
211104, Applied Physics - Philadelphia University Jordan
211104, Applied Physics - Philadelphia University Jordan

... Work Energy and Power: Introduction, work done by a constant force, work and kinetic energy, potential energy and conservative forces, dissipative forces, the work energy theorem, solving problems using the work energy theorem [3 hours]. ...
Nickel-Titanium Memory Metal
Nickel-Titanium Memory Metal

... where it can be trained to “remember” a new shape. Subsequently, when the wire is distorted at room temperature and heated by hot air or water, it will return to this new shape. Rods of NiTi can be used to show that the flexibility, hardness, and even its acoustic characteristics are all affected by ...
Chapter 1: Basic Concepts of Thermodynamics Thermodynamics
Chapter 1: Basic Concepts of Thermodynamics Thermodynamics

Chapter 2: Basic Concepts of Thermodynamics Thermodynamics
Chapter 2: Basic Concepts of Thermodynamics Thermodynamics

... Any characteristic of a system is called a property. In classical thermodynamics, the substance is ass umed to be a continuum, homogenous matter with no microscopic holes. This as sumption holds as long as the volumes, and length scales are large with respect to the intermolecular spacing. Intensive ...
HNRS 227 Lecture #2 Chapters 2 and 3
HNRS 227 Lecture #2 Chapters 2 and 3

... weighs more per volume than the warmer air and pushes the warmer air out of the way as it sinks down to its lowest level. The warmer, less dense air sits on top of the cooler air because it weighs less per volume. ...
HNRS 227 Lecture #2 Chapters 2 and 3
HNRS 227 Lecture #2 Chapters 2 and 3

... weighs more per volume than the warmer air and pushes the warmer air out of the way as it sinks down to its lowest level. The warmer, less dense air sits on top of the cooler air because it weighs less per volume. ...
Gases I - ChemConnections
Gases I - ChemConnections

...  3. Particles exert no forces on each other. ...
Ch7 Atmospheric Energy and Moisture Pt1
Ch7 Atmospheric Energy and Moisture Pt1

... Transpiration is the process by which plants release water vapor into the atmosphere. Evapotranspiration refers to all the water vapor released into the atmosphere. Both processes require energy to change liquid water into water vapor. Evapotranspiration constitutes an energy input to the atmosphere ...
Slide 1
Slide 1

Elements of Science Midterm Exam Review Answer Key
Elements of Science Midterm Exam Review Answer Key

Lecture-X
Lecture-X

... Molecular Vibrations Suppose that two atoms of masses m1 and m2 are bound together in a molecule with energy so low that their separation is always close to the equilibrium value ro. With the parabola approximation, the effective spring constant is k=(d2U/dr2)Iro. How can we find the vibration freq ...
Work_Energy TN
Work_Energy TN

... Include units and labels for your axes. (See Sample Data.) Data values in table below will be variable, due to carts having slightly different masses. ...
4.1 Classical Thermodynamics: The First Law
4.1 Classical Thermodynamics: The First Law

... with a fluid and used a rotating paddle wheel, driven by falling weights, to stir the water. The container was thermally insulated and so the process was adiabatic. Joule measured the consequent rise in temperature of the fluid and noted that this change in the fluid’s properties was due to the work ...
Proof of the formula for the kinetic energy of an object
Proof of the formula for the kinetic energy of an object

... Kinetic energy The energy possessed by a body by virtue of its motion called the kinetic energy of the body. A rocket traveling to the Moon has kinetic energy as does a snail crawling along a wall. It is the kinetic energy of objects that makes them difficult to stop and the kinetic energy of the ai ...
Kinetic Energy - schoolphysics
Kinetic Energy - schoolphysics

... Kinetic energy The energy possessed by a body by virtue of its motion called the kinetic energy of the body. A rocket traveling to the Moon has kinetic energy as does a snail crawling along a wall. It is the kinetic energy of objects that makes them difficult to stop and the kinetic energy of the ai ...
Radiation - Newark Catholic High School
Radiation - Newark Catholic High School

... We can use words like hot and cold to describe temperature. Something is hot when its temperature is high. When you heat something its temperature increases. Temperature and heat have a proportional relationship. All of the matter around is made of tiny particles. The particles have kinetic energy b ...
Chapter 4 - UniMAP Portal
Chapter 4 - UniMAP Portal

weather-conduction-convection
weather-conduction-convection

ACOS Objectives
ACOS Objectives

Chapter 3. Energy and the First Law
Chapter 3. Energy and the First Law

... • Molecules possess energy of various forms. It includes kinetic energy due to the motion of the center of mass in space (translational kinetic energy). In case of polyatomic molecules possess rotational kinetic energy, vibrational energy, potential energy (as a result of interaction between differe ...
TAKS Objective V with background info edited
TAKS Objective V with background info edited

LECTURE 7 General Relations for a Homogeneous Substance For
LECTURE 7 General Relations for a Homogeneous Substance For

Chapter 14 The Ideal Gas Law and Kinetic Theory
Chapter 14 The Ideal Gas Law and Kinetic Theory

... c) The kinetic energy of the atoms in the gas is greater in B than in A. d) The frequency of collisions of the atoms with the walls of container B are greater than that for container A. e) The force that the atoms exert on the walls of container B are greater than in for those in container A. ...

Thermodynamic temperature